DE3920873A1 - electrolytic tumbling drum - has anode system in conformity with the charge displaced by rotation - Google Patents

Abstract

A tumbling drum for the electrolytic surface treatment of free running bulk material in aqueous solutions has a prismatic shape with perforated walls. Its anode system is arranged to be equidistant to the envelope around the charge which acquires a sideways shift. The tumbling drum (1) dips with its perforated hexagonal shell completely in the electrolyte of the vat (5). During rotation, the charge (2) forms a slope (A-D) with an envelope (ABCDA). The boxes of the anode system (31,32,33,34,35) are arranged in conformity with this envelope and are of e.g. titanium filled with soluble anode cubes. The boxes (33,34) are hinged to facilitate lowering and lifting of the drum. ADVANTAGE - This results in a considerable rise in both the quality and the quantity of the reduced surface layers (in the case of electrolytic polishing).

Description

The invention relates to a device for electrolytic Surface treatment of bulk materials in water Solutions consisting essentially of one that said Mass parts as a batch containing to their horizontal Longitudinally rotating submersible drum primarily prismatic Room form with perforated wall, and from one that said plunger associated anode system.

The dependence of the cathodic current efficiency on the The magnitude of the cathodic current density is known. It is likewise known that with increasing current density also the proportion of hydrogen reduction in general increases takes, and consequently a reduction in cathodic Electricity yield leads. To maximize the yield hold and more electroplating current in the dive to feed drum located batch, the  so-called open passage area, i.e. the cross section area of all perforations and their density in the drum coat - provided it is the dimensions of the batch forming mass parts allow it - maximally designed. A corresponding example are diving drums for the Treatment of electronic components, their perforated Wall consists of a mesh.

For heavier batches, however, it is absolutely necessary that the drum jacket from a solid perforated Plate made of an electrically non-conductive synthetic Coat exists. Operational experience shows that the possible open passage area of perforated coats of diving drums is below the amount of 20%.

The anodes generally hang vertically in two Rows along the elongated prismatic drum body in the electrolyte. Both rows of anodes are the same Distance to the jacket of the diving drum. The anodes themselves can be flat plates, soluble or insoluble or also as soluble anode cubes (balls) in flat Baskets made of titanium or another material.

Another known measure to increase electricity Recording the submersible drum is half the anodes circular around the lower half of the drum  to arrange such a uniform electrical Field between the anode system and the drum body deliver. The homogeneous field allows expansion the range of maximum permissible cathodic current densities also below the diving drums. Increases in current took the submersible drum in the order of magnitude of approximately 30% are possible without the limit of permissible cathodic To exceed current densities.

If you record the cross-section of a diving drum, so their coat generally appears as a rule moderate polygon (preferably as a hexagon) or as a circle. Form the anodes around the lower half of the Drum in a semicircle, are - based on the Longitudinal or rotational axis of the submersible drum - the cross section of the drum shell and the semicircular anode arrangement centrically symmetrical.

According to the prior art, the submersible drums and the anode systems assigned to them - regardless of whether these are rows of plate-shaped anodes or a semicircle shaped anodes acts - together a symmetrical structure.

The cathodically polarized batch of the submersible drum provides is a Farraday cage. The drum is more common assign only about a third of their content to the batch  filled; the electrolytic reduction process (the so-called called galvanizing) takes place exclusively in the peripheral Area of the batch, i.e. on its envelope surface.

The prismatic drum body rotates continuously and the, in the batch located on the submersible drum follows - according to its Dead weight - the rotating drum jacket in the Sense of rotation. This results in (on the type and quantity the mass parts and the speed of rotation) one Apex from which the batch parts over a Roll the inclined slope down again.

The batch becomes - in the sense of rotation - for the most part offset one of the two rows of anodes, whereby they simultaneously from the opposite row of anodes is removed.

If a semi-circular anode arrangement is provided, then occurs an analogous comparable state.

With the transfer of the batch to one of the two anodes rows also necessarily result in a shift (concentration) of the electroplating current to that area of the batch envelope area closest to this row of anodes. The cathodic current density of this area should, however do not exceed their upper limit; i.e. that  the cathodic current density in all other areas of the Batch envelope area significantly below the desired value lies. The uneven current density distribution over the entire scope of the batch inevitably has an unequal moderate qualitative and quantitative galvanization of the Mass parts and at the same time a significantly reduced Electroplating performance. These shortcomings after State of the art are known; they can in their out effects cannot be avoided in terms of magnitude.

The invention has for its object the highest area permissible cathodic (in the case of the so-called electro lytic polishing of anodic current densities everywhere on the envelope surface of the batch of drums, if possible above their expand evenly across the scale to both the quality as well as the quantity of electrolytically reduced metal layers on the surfaces of the masses parts to increase significantly, and thus, in this Context known deficiencies in the prior art largely excluded.

The object is achieved in that the Batch-compliant anode system, i.e. essentially in equidistant distances from the envelope surface ABCDA of the one in which Submersible drum assigned batch, and the anodes system is therefore arranged asymmetrically to the submersible drum.  

The basic inventive idea can be figuratively ver can be illustrated by using the concentric wrapping the batch of drums with one equidistant on all sides comparing the anode system with a hand that in a glove. The real objective of Invention is the weakest area of the electric field, namely along the embankment area of the batch, to be activated as intensively as possible and so that the batch is also permissible at this point To provide maximum electroplating current.

The experimental realization of the subject of the invention surprisingly has a surge of the electroplating current while maintaining the permissible cathodic current densities and at the same time one Decrease in the applied rectifier voltage. The quality of the rainfall was clearly better, especially when electroplating electronic components in a Pb-Sn electrolyte. The metal layers were so good even with relatively small thicknesses of around 8 µm how non-porous; a sign that the cathodic Electricity yield converged to 100% and therefore only one negligibly small amount of hydrogen deposited has been.

The submersible drums are about a third of their fill load volume with the batch. If you measure the envelope surface the batch along the slope surface previously described  and if you also measure the proportion of the remaining batch Envelope surface on the perforated wall of the plunge drum rests, you will find that it is behave like 2: 3. So it succeeds in that Area of the slope level is a cathodic current to create density, that of the rest Batch surface (the one on the perforated drum jacket) is the same or approximately the same, you will achieve one Increase in total electroplating performance by is about a third higher than those after State of the art would be possible.

Between the two counter electrodes, i.e. between the enveloping anode system according to the invention and the batch there is a homogeneous electric field with an uneven one usually large conductor cross section for the flow of the Electroplating current. Observations in the operational Practice has shown that - with increased electroplating current - the rectifier voltage required for this falls considerably. A drastically reduced tension but means a drastically reduced consumption rectified electrical energy, and in particular in the case of galvanizing in drums, a ent speaking low energy requirements for cooling the Electrolytes.  

The significantly increased electroplating performance is said to also viewed in two different ways will:

• 1. With a (comparable) throughput with one conventional system can be a system with the Batch-compliant anode system according to the invention be dimensioned significantly smaller or
• 2. compared to a conventional system Dimension becomes one with batch-conforming anodes a significantly higher throughput of surfaces achieve treated batches.

The known assignments of anodes and immersion drums are symmetrical. The concentric order according to the invention coating the batch with an equidistant anode system has the consequence that the known device symmetrical anode plunger arrangement no longer is possible. The anode immersion drum according to the invention Arrangement stands in sharp contrast to the stand technology through asymmetry.

Taking into account the cross section of a submersible drum and if it turns counterclockwise, for example the batch moves over by the rotational movement weighing part in the right side of the illustrated Drum.  

The entire anode system also follows the invention this local shift and move to the right, the geometric center of the diving drum is not more - in contrast to the prior art - identical with the center of the assigned anode system. The batch-conforming anode system according to the invention can therefore in connection with the assigned diving drum no more than a geometrically regular structure to be sought.

The drum is mostly in systems for the upper surface treatment with an automatic transport mechanism are equipped. Lift individual carriages and lower the diving drum at the individual treatment stations and transport them according to specified time-distance Diagrams from one station to another.

According to the invention that can, the submersible cylinder shaped anode system at its top be interrupted to allow the dolly give the relevant immersion drum out of the electrolyte to raise or lower into this. The open one Position in the anode system is therefore directly above the Diving drum and has approximately the same width.  

Another variant of the invention provides that previously Open space described in the anode system can be closed with a segment of the right size. The removable segment closes the gap in the anode system as soon as the immersion drum into the electrolyte was lowered. After the treatment time has expired, the segment is removed to remove the drum from the Being able to lift the bath solution out. The insertion or Removal of the anode segment can be done in accordance with the Transport mechanism rhythm controlled automatically will.

Another simplified variant of the invention lets the use of the most in operational practice usual flat anode plates or boxes made of titanium, filled with soluble anode cubes or balls. The Submersible drum is between two, to each other parallel straight rows of such anodes, the lower hang right into the electrolyte. The said however, both rows of anodes show - in contrast to the stand the technology and in the sense of the asymmetry according to the invention - unequal distances to the drum body. The sense of rotation according to the drum is the row of anodes on which the Batch migrates farthest from the drum.  

A preferred embodiment of the invention provides before also closing the anodes on the two ends of the drum organize. The drum shell is consequently from all sides batch-conforming anode system encased; the additional anodes provided at both ends protrude preferably perpendicular to the horizontal axis of rotation of the Diving drum. The removal of the anodes at the end Submersible drum is also equidistant in relation to the Batch, i.e., the longitudinal and end anodes at an equidistant distance from the envelope surface of the drum batch.

With a drum of 900 mm length, a wrench size of 360 mm and perforations of 3 mm in diameter has been experimentally found that in a Add the additional anodes to the two ends sides of the drum whose current consumption by a further 18% can increase.

The end faces of the prismatic plunge drum are - with very few exceptions - never perforated. It goes without saying that in the invention Connection a perforation of the two end sides makes a further contribution to increasing performance.

To increase performance by means of batch-compliant Use the anode system as completely as possible the submersible drum should be completely in the electro Immerse the lyte.

The invention is illustrated schematically in some Embodiments described in more detail. The following Figures intend one on the essentials of the Devices according to the invention limited representation reproduce; known, familiar to the expert Construction elements are therefore not drawn considered.

Fig. 1 illustrates - in principle - the cross section of a drum immersed in the electrolyte with the batch therein, surrounded by the batch-compliant anode system according to the invention arranged at an equidistant distance from the batch.

FIG. 2 shows in cross section an exemplary embodiment corresponding to the basic illustration in FIG. 1.

FIGS. 3 and FIG. 4 illustrate the batches compliant anode assembly of Fig. 2 in a longitudinal view and in plan view (corresponding to the section MN of FIG. 2).

Fig. 5 shows the same assignment of the anode system according to the invention to the drum batch as in Figs. 1 to 4 with the difference that an anode area directly above the plunger drum is left open to a vertical sinking in or lifting the plunger drum out of the To be able to lead electrolytes.

FIG. 6 shows a simplified embodiment of the example shown in FIG. 5. Instead of the anode baskets containing soluble anode pieces, plate-shaped solid anodes are used.

FIGS. 7 and 8 illustrate variations of the exemplary embodiments in FIGS . 5 and 6 in that the end sides of the immersion drum are not provided with perforations and the conformal anode system is only assigned along the prismatic drum cylinder.

The hexagonal immersion drum 1 has a perforated jacket, is completely immersed in the electrolyte of the tub 5 and rotates about the horizontal longitudinal axis in the sense of the arrow entered. The end sides 11 of the immersion drum 1 are provided with interchangeable cylindrical inserts 12 , the bottoms of which have sieve-like perforations.

Batch 2 of pourable bulk parts is in the submersible drum 1 .

The removable cover 13 closes an opening in the casing of the immersion drum 1 , which is intended for loading or unloading the drum 1 with the batch 2 .

The batch 2 follows the drum shell 1 in the direction of rotation due to its own weight by moving in this direction and forming an embankment surface AD, over which the mass parts roll down in a regular periodic repetition. Batch 2 forms a Faraday cage; that is, the electrolytic reduction process takes place - essentially - exclusively on its envelope surface ABCDA.

According to the invention, the anode system 3 is assigned to the charge 2 at an equidistant distance. The batch shift in the direction of rotation of the immersion drum 1 consequently requires - in contrast to the prior art - an asymmetrical arrangement of the anode system 3 according to the invention relative to the immersion drum 1 . The asymmetry is obvious and can easily be seen in FIG. 1. Sets to a horizontal plane through the rotational axis of the immersion drum 1 through it, and brings these to the intersection with the illustrated anode system 3, so raising the order of magnitude of unequal proprieties a and b between the two parts of the anode system 3 and the drum shell 1, the apparent asymmetry of the arrangement according to the invention clearly.

The same statement regarding asymmetry applies mutatis mutandis also in the vertical direction; the unequal distances c and d prove it.  

Fig. 1 illustrates in principle - as a model - the basic idea of the invention. A dash-dotted line 3 can be seen in FIG. 1, which symbolizes the batch-conforming anode system 3 according to the invention and assigned to the envelope surface ABCDA of the drum charge 2 in an equidistant manner.

The drum cylinder 1 hangs on its two support arms 15 , which open into a horizontal bar 16 connecting them. The drivers 17 are intended for the carriage of the trans port mechanism, which conveys the immersion drum 1 according to a predetermined time-distance diagram from one trough 5 of the system for the surface treatment to the next. Due to the functional sequence of the electroplating process (immersion in and removal of the immersion drum from the electrolyte), the anode system 3 is expediently composed of a number of links 31 , 32 , 33 and 34 , which are chain-like, generally one in themselves form closed irregular ring 3 .

In the specific case of the exemplary embodiment, it is assumed that the anodes 3 are soluble and are filled as cubes or balls in the anode boxes 31 , 32 , 33 and 34 (for example made of titanium).

In order to allow the vertical movement of the sinking and lifting of the immersion drum 1 into and out of the electrolyte according to the vertical arrows in FIGS. 2 and 3, the corresponding upper two anode segments 33 and 34 are about their axes of rotation P and Q, respectively pivoted. The segments 33 and 34 are shown in broken lines in their swung out upper positions 33 'and 34 ' in FIG. 2. Their directions of movement are indicated by the associated double arrows.

The anode boxes 31 , 32 , 33 and 34 offer the favorable constructive possibility of giving the anode system 3 the most expedient spatial shape according to the invention. The arrangement 3 conforms to the charge 2 equidistantly and forms a probably cylindrical irregular and concentric as well as parallel but not centrically symmetrical housing 3 around the drum casing 1 .

Starting from the same task, ie making the electric field as homogeneous as possible over the entire envelope surface ABCDA of the batch 2 and thus reinforcing it, the invention proposes additional anodes 35 also in the region of the two end sides 11 of the drum 1 to provide. It can be seen in particular from FIG. 4 that the immersion drum 1 is also surrounded horizontally by an annular system formed from the anodes 31 , 32 and 35 . The distance of the anodes 35 to the end sides 11 is substantially the same as that of the longitudinal anodes 31 or 32 to the batch 2 ; They are therefore batch-compliant and equidistant to batch 2 .

The effect of the anodes 35 arranged on the end sides of the drum 1 is not only limited to delivering additional electroplating current to the batch 2 through the perforated inserts 12 of the end sides 11 , but they also have a field-strengthening effect due to the available open passage area of the drum shell 1 (ie through all perforations of the submersible drum 1 ) on the entire envelope surface ABCDA of batch 2 .

The additional arrangement of the anodes 35 consequently corresponds to the basic idea of the invention, to encapsulate the batch 2 completely in an anode system 3 , the elements 31 , 32 , 33 , 34 and 35 of which encompass the batch 2 in the submersible drum 1 , ie, equidistantly, spatially on all sides .

A variant of the subject matter of the invention, particularly in automatic systems with frequent consequences of lowering and lifting the submersible drum 1 in relatively short time intervals, provides for the otherwise preferably closed ring of the anode system 3 to be interrupted and the area directly above the submersible drum 1 to be left open. The anode segments 33 and 34 are omitted. Fig. 5 illustrates one such embodiment of the invention in principle. The characterizing feature of modern fiction, asymmetry between the batches compliant anode system 3 and the immersion drum 1 remains undiminished thereby obtained in an obvious way. The width of the area of the anode system 3 that is left open corresponds to the order of magnitude to the diameter of the immersion drum 1 .

It is known that the soluble anodes are both Cubes and balls filled in titanium anode boxes, Steel and even made of plastics or even as a plane Plates can be used in operational practice.

The plate anodes, for example those made of nickel, have thicknesses of around 12 mm and widths of approximately 120 mm. Such plates are understandably under the conditions of the operating sites in which the surface treatment systems are not to be mechanically bent in order to assume spatial shapes that are comparable to those of the anode boxes. In order nevertheless to take account of the conditions of operational practice when using such plate anodes, the invention proposes to arrange the batch-conforming anode systems 3 in accordance with the exemplary embodiment in FIG. 6.

The flat and flat anode plates 36 , 37 and 38 hang vertically in the electrolyte of the tub 5 . The anode rows 36 and 37 run parallel to the drum cylinder 1 at equidistant distances from the drum batch 2 . The, placed in a semicircle-like arc plate anodes 38 surround the two end sides 11 of the plunger drum 1 at radial distances which, based on the batch 2 , can also be described as equidistant.

The plate anodes 36 , 37 and 38 form in their connected overall unit the system 3 according to the batch and anode 36 , 37 and 38 arranged in a batch-equidistant manner to the batch 2 , the distances a and b of the anode rows 36 and 37 to the drum cylinder 1 being unequal are great.

FIGS. 7 and 8 show embodiments of the invention, based on immersion drums 1, the end faces 11 are not equipped with the perforated inserts 12. Despite the undeniably favorable influence on the build-up of a homogeneous electric field around the charge 2 , in practice one is occasionally forced to dispense with the circular arrangement of anodes 35 according to the invention in the region of the end faces of the drum 11 . However, this constraint has no significant disadvantageous effect on the effectiveness of the anode system 3 according to the invention.

FIG. 7 illustrates such a specific case when using batch-conforming anode boxes filled with soluble anode pieces.

It is known that it is structurally simple to give the lower part of the anode boxes 31 and 32 the spatial shape of a regular quarter circle UV or VW. If the two anode boxes 31 and 32 are joined together in the electrolyte, they together form the semicircle UVW with the center 0 and the radius r.

The equidistant distances between the anode system 3 according to the invention, consisting of the anode boxes 31 and 32 as components, and the drum batch have the consequence that the distances a and b of the batch-conforming anode system 3 to the drum cylinder 1 are unequal. As a further characteristic feature of the invention, the geometric location of the center 0 of the semi-circle UVW is to be considered; it is different from the location of the longitudinal (rotational) axis of the drum 1 .

The anode boxes 31 and 32 often have a flat, straight spatial shape similar to that of the aforementioned plate anodes 36 , 37 and 38 .

Analogous to the exemplary embodiment in FIG. 7, the illustration in FIG. 8 illustrates the invention analogously when using the solid flat plate anodes 36 and 37 . The equidistant distance between the two batch-conforming rectilinear anodes 36 and 37 from the drum batch 2 and their unequal distances a and b from the drum cylinder 1 characterize the use of the anode system 3 according to the invention in the present application.

The same statement obviously also applies in the case of flat, flat anode baskets, which essentially occupy the same positions as the batch-conforming plate anodes 36 and 37 of the exemplary embodiment according to the invention in FIG. 8.

Claims (10)

1. Apparatus for the electrolytic surface treatment of pourable bulk parts in aqueous solutions, consisting essentially of a diving drum containing the said mass parts as a batch and rotating about its horizontal longitudinal axis, primarily a prismatic three-dimensional shape with perforated wall, and an anode system associated with said diving drum, characterized in that the anode system ( 3 ) conforms to the batch, ie essentially at equidistant distances from the envelope surface ABCDA, of the batch ( 2 ) contained in the immersion drum ( 1 ) and the anode system ( 3 ) consequently asymmetrically to the immersion drum ( 1 ) is arranged. 2. Device according to claim 1, characterized in that the submersible drum ( 1 ) is located between two substantially parallel rows of anodes ( 31 , 32 or 36 , 37 ) arranged on both sides of the submersible drum ( 1 ) parallel to the latter and their mean distances a and b to the submersible drum ( 1 ) are not the same size. 3. Device according to claims 1 and 2, characterized in that the submersible drum ( 1 ) is located within an anode system ( 3 ) which is essentially concentric, but not centrically symmetrical around it, the mean distances of which to the envelope surface ABCDA Batch ( 2 ) are essentially identical to one another, ie are equidistant. 4. Device according to claims 1 to 3, characterized in that the cylindrical anode arrangement ( 3 ) around the drum ( 1 ) is interrupted by a missing segment, approximately the same width as the drum diameter, which segment is directly above the submersible drum ( 1 ) is to allow a vertical sinking in or lifting out of the submersible drum ( 1 ) from the tub ( 5 ). 5. Device according to claims 1 to 4, characterized in that segments ( 33 , 34 ) of the cylindrical anode arrangement ( 3 ) as required from the anode arrangement ( 3 ), for example by pivoting, can be removed or reinserted into this. 6. Device according to claims 1 to 5, characterized in that the immersion drum (1) between two anode rows (36, 37) of vertically in the electric LYTEN hanging anodes (36, 37) mainly flat plate-like spatial shape is that are arranged at unequal intervals a and b relative to the submersible drum ( 1 ). 7. Device according to claims 1 to 5 and in particular according to claim 6, characterized in that the lower ends of the vertically hanging in the electrolyte anodes ( 31 , 32 ) of the two opposite anodes ( 31 , 32 ) by preferably semicircular extensions ( 31 , 32 ) of their lower ends or, if necessary, are bent concentrically towards the immersion drum ( 1 ). 8. Device according to claims 1 to 7, characterized in that in addition to the anodes ( 31 , 32 , 36 , 37 ) along the immersion drum ( 1 ) further anodes ( 35 , 38 ) on the end sides ( 11 ) of the immersion drum ( 1 ) are arranged, the planes of which are preferably perpendicular to the longitudinal axis of the immersion drum ( 1 ). 9. Device according to claims 1 to 8, characterized in that the immersion drum ( 1 ) is completely immersed in the electrolyte. 10. Device according to claims 1 to 9, characterized in that the two end sides ( 11 ) of the plunging drum ( 1 ) are perforated or equipped with interchangeable perforated inserts ( 12 ).